MURATA-PS ADS-230

®
ADS-230/ADS-231
®
Low-Power, 12-Bit, 1.0/1.5MHz
Sampling A/D Converter
FEATURES
•
•
•
•
•
•
•
•
•
•
•
12-bit resolution
1.0 and 1.5MHz throughput rates
Small 44-pin Leaded Chip Carrier
Single +5V supply
Low power, 75 and 200mW maximum
Low power "standby" mode
Outstanding dynamic performance
No missing codes over temperature
Built-in sample-and-hold
Optional two-channel input multiplexer
Ideal for both time and frequency-domain applications
INPUT/OUTPUT CONNECTIONS
PIN
FUNCTION
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
GENERAL DESCRIPTION
The ADS-230 and ADS-231 are 12-bit, high speed CMOS
sampling analog-to-digital converters capable of minimum
sampling rates of 1.0 and 1.5MHz, respectively. Both models
feature excellent dynamic performance including a typical
SNR of 72dB for the ADS-230 and 70dB for the ADS-231.
The ADS-230 and ADS-231 are packaged in a small 44-pin
plastic Leaded Chip Carrier (LCC). Each model contains a
fast-settling sample/hold amplifier, a multipass (three-step
flash) A/D converter, timing and control logic, three-state
outputs, a two-channel multiplexer, and digital error correction
circuitry. Digital input and output levels are TTL.
Requiring only a single +5V supply, the ADS-230 typically
dissipates only 60mW and the ADS-231 only 170mW. Both
models offer a low-power "standby" mode resulting in typical
power dissipations of 100µW and 250µW, respectively. The
units offer a maximum unipolar input range of 0 to +5V. The
exact value of the input range is determined by an externally
applied reference voltage. Both models operate over the
extended –40 to +85°C temperature range.
AGND
VBS
VB
VR/16
VT
VTS
CH1IN
NC
CH2IN
NC
MUX OUT
ANALOG INPUT
AGND
AVS
DGND C
SEL
PD
DGND C
MD
OE
RD
S/H
AVS
DVS
VTS
VT
VR/16
VB
VBS
14,44
25
6
5
4
3
2
SAMPLE
AND HOLD
ANALOG INPUT 12
PIN
12-BIT A/D CONVERTER
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
OUTPUT LATCH
AND
THREE-STATE
BUFFER
MUX OUT 11
CH1IN
7
MULTIPLEXER
CH2IN
FUNCTION
AVS
BIT 1 (MSB)
BIT 2
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
BIT 9
NC
BIT 10
BIT 11
BIT 12 (LSB)
EOC
INT
NC
DGND D
DGND C
DVS
TEST
CS
PIN
43
42
41
40
39
38
37
36
35
33
32
31
BIT 1 (MSB)
BIT 2
BIT 3
BIT 4
BIT 5
BIT 6
BIT 7
BIT 8
BIT 9
BIT 10
BIT 11
BIT 12 (LSB)
29
INT
30
EOC
TIMING AND CONTROL CIRCUITRY
9
16
26,18,15
27
1,13
24
23
22
21
20
19
17
SEL
DGND C
DGND D
AGND
TEST
CS
S/H
RD
OE
MD
PD
Figure 1. ADS-220/-231 Simplified Block Diagram
DATEL, Inc., Mansfield, MA 02048 (U.S.A.) • Tel: (508) 339-3000, (800) 233-2765 Fax: (508) 339-6356 • Email: [email protected] • Internet: www.datel.com
®
ADS-230/ADS-231
PHYSICAL/ENVIRONMENTAL
ABSOLUTE MAXIMUM RATINGS
PARAMETERS
Supply Voltages
(VS = AVS = DVS)
Input or Output Voltage, any pin
Input Current, any pin ➀
Total Package Input Current, ➀
Power Dissipation, ➁
ESD Susceptibilty, ➂
Soldering, Infrared, 15 seconds
®
LIMITS
UNITS
–0.3 to +6
–0.3 to V S +0.3
25
50
875
2000
+300
V
V
mA
mA
mW
V
°C
PARAMETERS
MIN.
Operating Temp. Range TA = T J
Thermal Impedance, θja
Maximum Junction Temp. TJMAX
Storage Temperature Range
Package Type
TYP.
MAX.
UNITS
–40
—
+85
°C
—
55
—
°C/Watt
—
—
+150
°C
–65
—
+150
°C
44-pin Plastic Leaded Chip Carrier
FUNCTIONAL SPECIFICATIONS
(The following specifications apply for T A = T J = 25°C, DV S = AVS = 5.0V, V TS = +4.096V, V BS = AGND, RS = 25ohms and FS = 1.0/1.5MHz for the ADS-230/231 respectively, unless
otherwise specified.)
+25°C
ANALOG INPUT
Input Voltage Range (Pins 7, 9, 12)
Input Leakage Current
Input Capacitance
MUX On/Off-Channel Leakage
MUX Input Capacitance
MUX Off-Channel Isolation
FIN = 100kHz, –0dB
ADS-230
–40 to +85°C
+25°C
ADS-231
–40 to +85°C
TYP.
MIN.
MAX.
TYP.
MIN.
MAX.
UNITS
—
0.1
25
0.1
7
–0.05
—
—
—
—
AVS+0.05
3
—
3
—
—
0.1
25
0.1
7
–0.05
—
—
—
—
AVS+0.05
3
—
3
—
V
µA
pF
µA
pF
92
—
—
92
—
—
dB
—
—
750
—
0
500
AVS
—
1000
—
—
750
—
0
500
AVS
—
1000
V
V
Ohms
—
—
0.1
0.1
4
—
2
—
—
—
—
5
—
0.8
1
1
—
550
—
—
0.1
0.1
4
—
2
—
—
—
—
5
—
0.8
1
1
—
400
V
V
µA
µA
pF
ns
±0.4
±0.4
—
±0.3
±0.2
—
12
—
—
12
—
—
—
±1.5
±0.95
—
±2.0
±1.5
±1.0
±0.4
±0.4
—
±0.3
±0.3
—
12
—
—
12
—
—
—
±1.5
±0.95
—
±2.0
±1.5
±0.75
Bits
LSB
LSB
Bits
LSB
LSB
LSB
–82
—
–70
–80
—
–70
dB
72
69.5
—
70
67.5
—
dB
71
68
—
70
67
—
dB
–80
20
—
—
—
1
—
—
—
–80
20
—
—
—
1.5
—
—
—
dB
ns
MHz
REFERENCE INPUT
Reference Input + (Pin 6), V TS
Reference Input – (Pin 2), V BS
Reference Resistance
DIGITAL INPUT
Logic Levels
Logic "1", V S = 5.5V
Logic "0", V S = 4.5V
Logic Loading "1"
Logic Loading "0"
Digital Input Capacitance
S/H Pulse Width ➃, tS/H
STATIC PERFORMANCE
Resolution
Integral Nonlinearity
Differential Nonlinearity Error
No Missing Codes
Offset Error
Gain Error
Power Supply Sensitivity, (±10%)
DYNAMIC PERFORMANCE ➄
Total Harmonic Distortion (–0dB)
FIN = 100kHz ➅
Signal-to-Noise Ratio
(wo/distortion, –0dB) FIN = 100kHz
Signal-to-Noise Ratio ➆
(& distortion, –0dB) FIN = 100kHz
Two-Tone Intermodulation Distortion
FIN = 102.3, 102.7kHz, (–0dB)
Aperature Delay Time, (tAD)
A/D Conversion Rate
2
®
®
ADS-230/ADS-231
+25°C
TIMING
Conversion Time, tCONV
Time for Conversion to Start, tEOC
Access Time, tACC (CL = 100pF)
Three-State Control Time, t1H, t0H
RL = 1k, CL = 10pF
Delay Time, RD Low to INT High
tINTH, CL = 100pF
Delay Time, EOC High to INT Low
tINTL, CL = 100pF
EOC High to Data Valid, tUPDATE
MUX Address Setup Time, tMS
MUX Address Hold Time, tMH
CS Setup Time, tCSS
CS Hold Time, tCSH
Wake-up Time, tWU
PD High to First S/H Low
ADS-230
–40 to +85°C
+25°C
ADS-231
–40 to +85°C
TYP.
MIN.
MAX.
TYP.
MIN.
MAX.
UNITS
740
95
10
600
60
—
980
125
20
580
90
10
510
60
—
660
125
20
ns
ns
ns
25
—
40
25
—
40
ns
35
—
60
35
—
60
ns
25
5
—
—
—
—
35
—
50
50
20
20
10
15
—
—
—
—
25
5
—
—
—
—
35
—
50
50
20
20
10
15
—
—
—
—
ns
ns
ns
ns
ns
ns
1
—
—
1
—
—
µs
—
—
—
—
0.1
5
2.4
—
—
—
—
—
Binary
—
0.4
–360
1.6
3
—
—
—
—
—
0.1
5
2.4
—
—
—
—
—
Binary
—
0.4
–360
1.6
3
—
V
V
µA
mA
µA
pF
—
4.5
5.5
—
4.75
5.25
V
2
10
20
—
—
—
—
—
3
12
—
75
2
32
50
—
—
—
—
—
3
37
—
200
mA
mA
µA
mW
DIGITAL OUTPUT
Logic Levels
Logic "1" (VS = 4.5V)
Logic "0", (VS = 4.5V)
Logic Loading "1"
Logic Loading "0"
Three-State Output Leakage
Three-State Output Capacitance
Output Coding
POWER REQUIREMENTS
Power Supply Range
+5V Supply, V S = AVS = DVS
Power Supply Current
DVS Supply Current, DIS
AVS Supply Current, AIS
Standby Current (AIS +DIS, PD = 0) ➇
Power Dissipation
Footnotes:
➀ When the input voltage at any pin exceeds the power supply rails (below
GND or Above V S) the input current must be limited to ±25mA or less. The
package input current limits to two the number of pins that can meet this
constant.
➁ In most cases, the maximum derated power dissipation will be reached only
during fault conditions.
➂ This is the ESD rating for the human body model, with a 100pF capacitor
discharged through a 1.5 kilohm resistor. The ESD rating for the machine
model is 200V.
➃ For best performance, the rising edge of the S/H pulse must not be near
either the falling or rising edge of EOC. The recommended values of tS/H are:
ADS-230: 5ns<tS/H<40ns, or 150ns<tS/H<550ns
ADS-231: 5ns<tS/H<40ns, or 150ns<tS/H<400ns
➄ The MUX inputs CH1IN and CH2IN are not used during dynamic testing of these
models. The internal multiplexer adds harmonic distortion at high input frequencies.
See the Typical Performance Curves for THD with and without the MUX.
➅ The contributions from the first nine harmonics are used in the calculation of THD.
➆ Effective bits is equal to:
Full Scale Amplitude
(SNR + Distortion – 1.76 + [20 log Actual Input Amplitude ])
6.02
➇ Some units may have higher standby currents than the typical indicated. Production
testing of standby current is prohibitive due to the 10 second delay time on DIS after
PD is pulled low.
3
®
ADS-230/ADS-231
PIN DESCRIPTIONS
AVS, DVS
These are the analog and digital power supply input pins. They should all be connected to
the same voltage source. Both AVS pins should be bypassed to AGND and the DVS pin to
DGNDD. Bypass using a 0.1µF ceramic capacitor in parallel with a 10µF tantalum
capacitor.
AGND, DGNDC, DGNDD
These are the analog and digital ground pins. All of the ground pins should be returned to
the same potential and connected to a stable, noise-free system ground. AGND is the
analog ground. DGNDC is the ground for the digital control lines. DGNDD is the digital
ground for the output data bus.
BIT 1 – BIT 12
These are the three-state data output pins. Output is enabled by RD, CS, and OE.
CH1IN, CH2IN
These are the analog input pins to the internal input multiplexer.
MUX OUT
This is the output of the internal multiplexer,
ANALOG INPUT
This is the direct input to the sampling A to D converter.
SEL
This is the multiplexer channel select pin. The input is selected based on the state of SEL
when EOC transitions low. A low selects channel one and a high selects channel two. See
Table 1.
MD
Connect to DGNDC
TEST
Connect to DVS.
CS
This is the Chip Select control input. When low, this pin enables the RD, S/H and OE inputs.
This pin can be tied low.
INT
This is the Interrupt output pin. When using the Interrupt Interface Mode, this output goes
low when a conversion is completed and indicates that the data is available in the output
latches. This output is always high when RD is held low. Refer to the Timing Diagrams.
EOC
This is the End of Conversion output pin. EOC is low during a conversion.
RD
This is the Read control input pin. When RD and CS are low, the INT output is reset and, if
EOC is high, data appears on the data bus. This pin can be tied low.
OE
This is the Output Enable control input pin. The data output pins are in the high impedance
state when OE is low. Data appears when OE is high and CS and RD are both low. This pin
can be tied high.
S/H
This is the Sample and Hold control input pin. When CS is low a new conversion is initiated
by the falling edge of this input.
PD
This is the Power Down control input pin. This pin is held high for normal operation. When
the input is low, the A to D converter goes into power standby mode.
VR/16
Bypass this pin to AGND using a 0.1µF ceramic capacitor.
VT, VB
These are the positive (top) and negative (bottom) voltage reference force input pins,
respectively.
VTS, VBS
These are the positive (top) and negative (bottom) voltage reference sense pins,
respectively.
4
®
®
®
ADS-230/ADS-231
TECHNICAL NOTES
Table 1 shows the coding for MUX channel selection.
The Analog Input
The output of the MUX is available at the MUX OUT pin. This
output allows the user to perform additional signal processing,
such as buffering, filtering or gain, before the signal is brought
to the ANALOG INPUT pin. If signal processing is not required
connect the MUX OUT pin directly to the ANALOG INPUT pin.
For maximum performance, the source impedance driving the
input of the ADS-230/-231 should be as low as possible. A
source impedance of less than 100 ohms is recommended.
See the Typical Performance Curves.
If the signal source has high output impedance, the output
should be buffered with an op-amp capable of driving a
switched 25pF/100ohm load. Any ringing or instability of the
op-amp during the sampling period can cause conversion
errors.
Table 1. Internal Multiplexer Programming
Using a high-speed buffer also improves the THD
performance when using the internal MUX. The MUX onresistance is non-linear over the range of the input voltage;
this causes the RC time constant of the equivalent circuit
shown in Figure 2 to vary with input voltage. This results in
harmonic distortion with increasing frequency. Inserting a
buffer between the MUX OUT and ANALOG INPUT terminals
will eliminate the loading on RMUX and significantly reduce
THD.
SEL
Channel
0
CH1IN
1
CH2IN
ADS-230/231
CH1IN
RMUX
RS
CH2IN
MUX OUT
The analog input of the ADS-230/-231 can be modeled as
shown in Figure 2. The S/H switch is closed during the sample
period, and open during hold. The hold capacitor (CH) has to
be charged to the input voltage by the source within the
sample period. The source impedance (RS) will directly effect
the charge time. If RS is too large, the voltage across CH will
not settle to within ½ LSB's of the source voltage before
conversion begins. This will result in conversion errors.
ANALOG
INPUT
VSOURCE
RSW
S/H
SWITCH
TYPICAL VALUES
RMUX = 100
RSW = 100
CH = 25pF
TO COMPARATORS
CH
Figure 2. ADS-230/-231 Input Stage Model
The combination of RS, RMUX, RSW and CH form a low-pass
filter. Therefore, minimizing RS will increase the frequency
response of the converter.
VTS NC
+5V ±5%
The settling time to n bits is:
4.093V
4.096V
60Ω
VT
tSETTLE = (RS + RMUX + RSW ) * CH * n * In(2)
10µF
The bandwidth of the input circuit is:
0.1µF
F (–3dB) = 1/[2 * 3.14 * (RS + RMUX + RSW ) * CH]
Internal Multiplexer
Both the ADS-230 and ADS-231 have an internal multiplexer
that is controlled by the logic level on the SEL pin when EOC
goes low. See the timing diagrams. The MUX setup and hold
times can be determined from the following:
VR/16
tMS(wrt S/H) = tMS –tEOC (min)
tMS(wrt S/H) = 50–60
tMS(wrt S/H) = –10ns
0.1µF
REFERENCE
LADDER
ADS-230/231
tMH(wrt S/H) = tMH + tEOC (max)
tMH(wrt S/H) = 50 +125
tMH(wrt S/H) = 175ns
Note that the –10ns indicates that data on SEL must be valid
within 10ns of the S/H pulse going low in order to meet the
setup time requirements. SEL must be valid for the length of
time determined by the following equation:
(tMS + tEOC(max)) – (tMS – tEOC (min)) = 185ns
VB
0.003V
VBS NC
Figure 3. Reference Force Input Only
5
®
ADS-230/ADS-231
4.096V
1~0µA
1kΩ
VTS
RS
®
SENSE LINE
4.096V
+5V
0.01µF
500Ω
1kΩ
VT = 4.096V
LM4040–4.1
VT
FORCE LINE
10µF
1=5.9mA
Rf
0.1µF
7.02V
VR = VT – VB = 4.096V
Rf = 0.5Ω (FORCE LINE IMPEDANCE)
RS = 10Ω (SENSE LINE IMPEDANCE)
RLADDER = 750Ω
VR/16
REFERENCE
LADDER
0.1µF
ADS-230/231
–2.93V
1 = 5.9mA
VB = 0.000V
–0.003V
500Ω
VB
Rf
FORCE LINE
0.000V
0.01µF
10µF
0.1µF
0.000V
1kΩ
VBS
1~0µA
RS
SENSE LINE
Figure 4. Ladder Reference Force and Sense Inputs
Reference Inputs
Reference voltages are applied to the fully differential VT
and VB reference input pins. The resistance of the reference ladder network is typically 750 ohms. Additional
parasitic resistances are added by the package leads, wire
bonds, conductor traces, etc. These parasitic resistances
can introduce voltage drops causing gain and offset errors
as large as 6 LSB's at the 12-bit level. These IR drops can
be compensated for by sensing the reference voltages at
the VTS and VBS reference sense pins and forcing the
reference voltage an exact value as shown in Figure 4.
configuration with a low offset voltage op-amp, gain and
offset errors below 0.5 LSB are readily obtainable.
The 0.1 and 10µF capacitors on the force inputs provide
high frequency decoupling of the reference ladder network.
The 500Ω force resistors isolate the op-amp from the large
capacitive load. The 0.01µF and 1kΩ network ensures
stability at high frequencies. The VR/16 output should be
bypassed to analog ground with a 0.1µF ceramic capacitor.
All bypass capacitors should be located as close to the
pins as possible to minimize noise on the reference ladder.
Since there is essentially zero current flowing through the
sense line there is negligible voltage drop to the inverting
input of the op-amp. The voltage at the inverting input of
the op-amp, therefore, accurately represents the voltage at
the top or bottom of the reference ladder network. The opamp drives the force input and forces the voltages at the
ends of the reference ladder network to equal the voltage
at the op-amps non-inverting input, plus or minus the opamps input offset voltage. When using this reference
If the ADS-230/-231 is used in a frequency domain
application then the circuit shown in Figure 3 maybe used.
This circuit will introduce several LSB's of gain and offset
error, but the dynamic performance will be unaffected.
The reference inputs are fully differential and define the fullscale range of the input signal. The maximum range can be
up to 5 volts, or when required any span within the 0 to 5V
limit may be used. When using lower voltage spans the
noise performance will degrade. See the Typical
Performance Curves.
6
®
®
ADS-230/ADS-231
Timing
indicating that the conversion results are latched and may
be read by pulling RD low. The falling edge of RD resets
the INT line.
The ADS-230/-231 has two modes of operation as shown
in Figure 5, 6, 7 and 8.
The High Speed Interface mode is shown in Figure 6. In
this mode the output data is always present, and the INT to
RD delay is eliminated.
In the Interrupt Interface mode, as shown in Figure 5, the
falling edge of S/H holds the input voltage and initiates a
conversion when CS is held low. At the end of conversion,
the EOC output goes high and the INT output goes low,
The control logic decoding section is shown in Figure 8.
tAD
INPUT
N
N+1
N+2
CS
tAD
tTHROUGHPUT
tCONV
INPUT
N
N+1
N+2
tS/H
S/H
tTHROUGHPUT
tCONV
tEOC
tS/H
S/H
EOC
tMS
tEOC
tMH
SEL
N+1
N+2
EOC
tINT
tMS
tMH
INT
SEL
N+1
N+2
tINTH
tUPDATE
IT 1 - BIT 12
RD
tACC
BIT 1 - BIT 12
DATA (N-1)
DATA (N-1)
DATA (N)
t1H.OH
DATA (N)
Figure 5. Interrupt Interface Timing (MD = 0, OE = 1)
tCSS
Figure 6. High-speed Interface Timing (MD = 0, OE = 1, CS = 0, RD = 0)
S/H
tCSH
ADS-230/231
CS
INTERNAL S/H
CS
S/H
INTERNAL OUTPUT
ENABLE
RD
RD
OE
INT
OE
INT FROM INTERNAL STATE MACHINE
Figure 7. CS Setup & Hold Timing for S/H, RD and OE
Figure 8. ADS Control Logic
7
®
ADS-230/ADS-231
®
Power Supply
interference in the analog circuitry thereby improving the
dynamic performance of the converter. When driving a high
capacitance digital data bus buffering the output data lines
maybe necessary to minimize the DVS and DGND current
spikes generated each conversion to charge the data bus
capacitance.
The ADS-230 and ADS-231 are designed to operate off a
single +5V supply. To guarantee proper operation of the
converters, only one power supply should be used. If
separate analog and digital supplies are used, then the
converter must be powered up with the analog supply. The
absolute maximum ratings states that all inputs must be
between GND –300mV and VS +300mV. When the
converter power supply is turned off the maximum input
becomes ±300mV, which in turn requires that the devices
connected to the converter have power removed before
power to the converter is removed.
These large current spikes will couple back to the analog
circuitry increasing the converter noise level. Separating
the digital outputs from the digital inputs reduces the
possibility of ground bounce from the data lines causing
jitter on the S/H input. The digital ground planes should be
tied together at the digital ground pins. The analog ground
plane should be tied to the DGNDD ground plane at the
ground return strap for the power supply.
There are two analog pins AVS and one digital supply pin
DVS. This allows for separate bypassing of the analog and
digital sections of the circuit. Both AVS pins should be
bypassed to ground with 0.1µF ceramic capacitors. At least
one of the AVS pins should be bypassed with a 10µF
tantalum capacitor. The DVS input should be bypassed with
a 0.1µF ceramic capacitor in parallel with a 10µF tantalum
capacitor. All bypass capacitor should be located as close
to the converter as possible.
S/H Input
The clock source driving the S/H input must be free of jitter.
For best performance, a crystal oscillator is recommended.
For the ADS-230 and ADS-231, a 1.0 and 1.5Mhz square
wave will provide a good signal for the respective S/H
inputs. In both cases, as long as the duty cycle is near
50%, the S/H pulse widths fall under the maximum allowed.
When operating the ADS-230 below 910kHz or the ADS231 below 1.25MHz, the S/H pulse widths must be less
than half the respective sample periods.
There are two analog ground pins (AGND), three digital
ground pins for the control inputs (DGNDC), and one digital
ground pin for the data output lines (DGNDD). Separating
the analog section from the digital sections reduces digital
8
®
®
ADS-230/ADS-231
SNR vs. Input Frequency
(Through Mux)
THD vs. Input Frequency
(Through Mux)
80
–80
70
70
–70
60
60
–60
50
50
–50
40
dB
80
dB
dB
SINAD vs. Input Frequency
(Through Mux)
40
–40
30
30
–30
20
20
–20
10
10
–10
0
0
10
100
1000
0
10
100
fIN (kHz)
1000
10
fIN (kHz)
SNR and THD
vs. Source Impedance
100
1000
fIN (kHz)
SNR and THD
vs. Reference Voltage
80
90
SNR
THD
70
80
60
fIN = 100kHz
50
40
dB
dB
70
60
30
20
50
SNR
THD
10
40
fIN = 100kHz
10
Note: Unless otherwise stated, the
following conditions apply:
0
100
1000
0
10000
1
2
3
4
DVS = AVS = 5.0V
REFERENCE VOLTAGE (VT – VB)(V)
SOURCE IMPEDANCE (Ω)
Conversion Time
vs. Temperature
TA = 25°C
fS = 1.0MHz
FFT
810
CONVERSION TIME (ns)
–20dB
790
780
–40dB
770
5.5V
–60dB
760
5.0V
750
–80dB
740
4.5V
730
–55 –35 –15 5
–100dB
25 45 65 85 105 125
100
AMBIENT TEMPERATURE (°C)
200
300
400
500
FREQUENCY (kHz)
SINAD vs. Input Frequency
(Analog In)
THD vs. Input Frequency
(Analog In)
SNR vs. Input Frequency
(Analog In)
80
80
70
70
–80
60
60
–70
50
50
40
–90
–60
dB
dB
dB
fIN = 0dB from full scale
0dB
800
40
–50
–40
30
30
20
20
10
10
0
0
10
100
fIN (kHz)
1000
–30
–20
–10
0
10
100
1000
fIN (kHz)
Typical Performance Curves for ADS-230
9
10
100
fIN (kHz)
1000
®
ADS-230/ADS-231
SNR vs. Input Frequency
(Through Mux)
THD vs. Input Frequency
(Through Mux)
80
–80
70
70
–70
60
60
–60
50
50
–50
40
dB
80
dB
dB
SINAD vs. Input Frequency
(Through Mux)
40
–40
30
30
–30
20
20
–20
10
10
–10
0
0
10
100
1000
®
0
10
100
fIN (kHz)
1000
10
100
fIN (kHz)
SNR and THD
vs. Source Impedance
85
SNR and THD
vs. Reference Voltage
90
SNR
THD
80
1000
fIN (kHz)
80
70
75
60
70
dB
dB
40
65
30
60
20
fIN = 100kH
55
Note: Unless otherwise stated, the
following conditions apply:
SNR
THD
10
0
50
10
DVS = AVS = 5.0V
fIN = 100kH
50
100
1000
10000
1
0
SOURCE IMPEDANCE (Ω)
2
3
4
REFERENCE VOLTAGE (VT – VB)(V)
TA = 25°C
fS = 1.5MHz
Conversion Time
vs. Temperature
fIN = 0dB from full scale
FFT
630
0dB
CONVERSION TIME (ns)
620
–20dB
610
–40dB
600
5.5V
590
–60dB
5.0V
–80dB
580
4.5V
570
–55 –35 –15 5
–100dB
25 45 65 85 105 125
100
AMBIENT TEMPERATURE (°C)
80
80
–90
70
70
–80
60
60
–70
50
50
400
500
–60
dB
40
300
THD vs. Input Frequency
(Analog In)
SNR vs. Input Frequency
(Analog In)
dB
dB
SINAD vs. Input Frequency
(Analog In)
200
FREQUENCY (kHz)
40
–50
–40
30
30
20
20
10
10
0
0
10
100
fIN (kHz)
1000
–30
–20
–10
0
10
100
1000
fIN (kHz)
Typical Performance Curves for ADS-231
10
10
100
fIN (kHz)
1000
®
®
ADS-230/ADS-231
Linearity Error
vs. Reference Voltage
±0.6
±1.25
±0.5
±1.00
±0.75
±0.50
FULLSCALE
±0.25
±0.3
±0.2
±0.1
OFFSET
300
260
3
4
5.0V
180
5.5V
140
100
1
5
2
3
4
60
0.0
5
REFERENCE VOLTAGE (VT –VB)(V)
REFERENCE VOLTAGE (VT –VB)(V)
Digital Supply Current
vs. Temperature vs. DVS
Analog Supply Current
vs. Temperature vs. AVS
5.0V
4.75V
2.0
1.9
–55 –35 –15 5
5.0V
4.75V
32
31
30
29
28
–55 –35 –15 5
25 45 65 85 105 125
AMBIENT TEMPERATURE (°C)
3.0
4.0
25 45 65 85 105 125
0
AMBIENT TEMPERATURE (°C)
1
2
3
INPUT VOLTAGE (V)
EOC Delay Time (tEOC)
vs. Temperature vs. VS
110
Note: Unless otherwise stated, the
following conditions apply:
DVS = AVS = 5.0V
TA = 25°C
105
100
4.75V
95
5.0V
5.25V
90
85
–55 –35 –15 5
25 45 65 85 105 125
AMBIENT TEMPERATURE (°C)
Typical Performance Curves, ADS-230/-231
11
5.0
260
240
220
200
180
160
140
120
100
80
60
40
20
0
DIGITAL SUPPLY CURRENT (µA)
2.2
2.0
Current Consumption in Standby Mode
vs. Voltage on Digital Input Pins
5.25V
33
1.0
ANALOG INPUT (V)
34
5.25V
4.5V
220
0.0
2
ANALOG SUPPLY CURRENT (mA)
DIGITAL SUPPLY CURRENT (mA)
340
±0.4
2.3
2.1
380
EOC DELAY TIME (tEOC) (ns)
±0.00
1
Mux ON Resistance
vs. Analog Input vs. VS
LINEARITY ERROR (LSB)
±1.50
LINEARITY ERROR (LSB)
OFFSET AND FULLSCALE ERROR
(LSB)
Offset and Fullscale Error
vs. Reference Voltage
4
5
®
®
ADS-230/ADS-231
MECHANICAL DIMENSIONS INCHES (mm)
6
0.650 - 0.656
(16.51 - 16.66)
PIN 1 INDENT
1 44
45° x 0.045
(1.14)
40
7
39
ADS-230/231
29
17
18
28
0.050
(1.27) TYP
0.500
(12.70) TYP
0.685 - 0.695
(17.40 - 17.65) TYP
0.026 - 0.032
(0.66 - 0.81) TYP
0.165 - 0.180
(4.19 - 4.57) TYP
45° x 0.045
(1.14)
0.090 - 0.130
(2.29 - 3.30) TYP
0.013 - 0.021
(0.33 - 0.53) TYP
0.020
(0.51) MIN TYP
0.590 - 0.630
(14.99 - 16.00) TYP
ORDERING INFORMATION
Model
ADS-230
ADS-231
Throughput Rate
1.0MHz
1.5MHz
Operating Temperature Range
–40°C to +85°C
–40°C to +85°C
ISO 9001
R
E
G
I
S
T
E
R
E
D
DS-0301
DATEL, Inc. 11 Cabot Boulevard, Mansfield, MA 02048-1151
Tel: (508) 339-3000 (800) 233-2765 Fax: (508) 339-6356
Internet: www.datel.com Email: [email protected]
Data sheet fax back: (508) 261-2857
03/97
DATEL (UK) LTD. Tadley, England Tel: (01256)-880444
DATEL S.A.R.L. Montigny Le Bretonneux, France Tel: 01-34-60-01-01
DATEL GmbH Munchen, Germany Tel: 89-544334-0
DATEL KK Tokyo, Japan Tel: 3-3779-1031, Osaka Tel: 6-354-2025
DATEL makes no representation that the use of its products in the circuits described herein, or the use of other technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained
herein do not imply the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change without notice. The DATEL logo is a registered DATEL, Inc. trademark.